RU190244U1 - INSTALLATION FOR THE STUDY OF DYNAMIC CHARACTERISTICS OF SOUND INSULATION MATERIALS - Google Patents

Abstract

This device relates to devices for the study and determination of the dynamic characteristics of sound-proofing materials under static loads and vibration effects and may be designed to determine the dynamic modulus of elasticity and the loss factor for different statistical loads. The technical effect of separating the static and dynamic effects on the sample under study, as well as increasing the accuracy and reliability of the tests, is achieved due to the fact that the electrodynamic vibrator is installed horizontally and sequentially with a test press, and its table is installed directly on the lower working plate of the test press and associated with the vibrator of the vibrator using a horizontal rod. 1 il.

Description

The utility model relates to the field of testing sound-proof materials, and more specifically to devices for studying and determining the dynamic characteristics of sound-proof materials under static loads and vibration effects, and can be used to determine the dynamic modulus of elasticity and loss factor for different magnitudes of static loads.

A device for measuring the dynamic characteristics of sound and vibration insulation materials by author. St. USSR №538287, IPC G01N 29/00. The device contains a vibration generator with a power winding and a support plate, which are rigidly fixed on a fixed base. The device also contains a load for pressing the test sample to the base plate. The load with the help of a pusher made of ferromagnetic material is connected with a vibration generator. Around the pusher in the base plate is an additional electric winding connected to the winding of the vibrator through a variable resistor and an electric valve. In addition, a control vibro-receiver connected to an oscilloscope is installed on the shipment. By eliminating the asymmetry of the amplitudes of the excited oscillations, the accuracy of measuring the dynamic characteristics is increased. The disadvantage is that the measurement of dynamic characteristics of this device is limited, since the static and dynamic effects on the sample under study are interrelated, it is impossible to separate them. To change the value of the static load, it is necessary to replace the weights, which is complicated in this device.

A known device for determining the dynamic characteristics of elastomers under the patent for useful model RU 158443, publ. 01/10/2016, and a device for implementing the method for determining the dynamic characteristics of elastomers according to the patent for invention RU 12557321, publ. 02/10/2015 Both of these devices are aimed at expanding the possibilities of measuring the dynamic characteristics of the material. This expansion is provided by changing and fixing the angle of inclination of the test sample to the surface of the table of the vibrator. Devices designed for this purpose contain a vibrator, on the table of which the material to be tested is installed between the two metal plates and glued to them. Top secured cargo. The devices also have devices for changing and fixing the angle of inclination of the material sample under study. However, to change the static load, the load must be changed and re-fastened on the holders of the sample under study.

The standard method and device for determining the dynamic characteristics of sound-proof materials is described in GOST 16297-80 "Sound-proof and sound-absorbing materials. Test methods. The measurement principle is based on the formation of an oscillatory system with one degree of freedom, for which the longitudinal rigidity of the sample of the material under study is determined from the natural frequency.

The installation for determining the dynamic modulus of elasticity and loss coefficient in accordance with clause 2.2.8 of the said GOST contains an electrodynamic vibrator, on the table of which a test sample is mounted. A load is mounted on top of the sample, on which the accelerometer is fixed, the second accelerometer is connected to the vibrator table. The installation also includes measuring amplifier and generator, power amplifier and vibration meter.

According to the test scheme carried out at the facility, the dynamic characteristics of sound-proof materials depend on the static load applied. The load depends on the mass of the weights, while an increase in the mass of the weights increases the dynamic effect on the material under study. In addition, electrodynamic exciters have insufficient power for measurements with prigruzym large mass. Therefore, the method of testing materials and the installation itself requires improvement.

Known test bench for determining the dynamic modulus of elasticity and loss factor for large static loads (S. Ovsyannikov, Skripchenko D.S. “Study of sound insulation properties of materials at various static loads”, UDC 699.842, “Technology of the textile industry”, No. 4 ( 364), 2016, Fig. 2 p. 41-42). This stand is closest to the proposed installation and adopted for the prototype. The bench of the prototype contains an LDS vibrator type V406 and press equipment (test press). Electrodynamic vibrator mounted vertically on the bottom working surface of the test press. Samples of the studied material are placed under the upper working plate of the test press on the electrodynamic vibrator table, driven by the vibration exciter. The stand includes the load for the sample and two accelerometers of type 4533-B. One accelerometer is mounted on the weights for the sample of material under study, and the other is mounted on the electrodynamic vibrator table. The installation of the weights and samples of the investigated material is carried out through elastic support inserts. The stand also includes measuring paths designed to connect accelerometers with a power amplifier, control unit and computer. The stand allows measurements at various static loads through the use of press equipment. However, the combined effect of static load and vibration creates in the sample forced oscillations and does not allow maintaining a constant amplitude of vibration acceleration of the table of the electrodynamic exciter. As a result, the accuracy and reliability of the test results is reduced.

The technical problem solved by the utility model is to separate the static and dynamic effects on the sample under investigation by improving the design of the device for studying the dynamic characteristics, and thereby ensure their independence from each other.

The solution of a technical problem allows to increase the accuracy and reliability of tests.

The problem is solved as follows.

The inventive installation for the study of the dynamic characteristics of sound-proof materials, as well as the prototype, contains a test press and an electrodynamic vibrator. The electrodynamic vibrator table associated with the exciter, as in the prototype, is installed under the upper working plate of the test press. The plant also includes the weights for the sample of the material under study and two accelerometers, one of which is connected to the vibrator table and the other with the load. For connecting accelerometers with a power amplifier, a control unit and a computer, measuring paths are available.

Unlike the prototype, the electrodynamic vibrator in the inventive installation is installed horizontally and sequentially with a test press, and its table is installed directly on the lower working plate of the test press and is connected to the vibrator exciter using a horizontal rod.

Since the electrodynamic vibrator and the test press are installed separately from each other, and the vibrator table is installed between the plates of the test press, forced oscillations arising from the joint (simultaneous) effects of a static load (from the test press) and vibratory (from the vibrator) are excluded. As a result, increases the accuracy of research.

The drawing shows the structural scheme of the inventive installation.

The installation contains an electrodynamic vibrator 1 mounted horizontally and in series with a test press on a single platform 2. Through the gasket material 3 between the top plate 5 and the bottom plate 6 of the press place the material under study 4. The installation includes measuring paths 7, which are designed to connect the accelerometer 8 with an amplifier power 9, the control unit 10 and a personal computer 15. Accelerometer 8 is mounted on the weft 11. The second accelerometer 12 is mounted on the table 14 of the vibrator 1. Accelerometers 8, 12 s using the measuring paths 7 are connected to the power amplifier 9, the control unit 10 and the personal computer 15. The table 14 of the vibrator 1 is connected to the vibrator of the vibrator 1 by means of an elongated horizontal rod 13.

Tests on the proposed installation shown in a specific example. Samples of sound insulation materials manufactured by both local and foreign manufacturers were investigated. The resonant frequency for the tested samples is set in the range of 10-200 Hz. As an electrodynamic vibrator 1, an LDS V406 vibrator was used. As a power amplifier 9 - PA100E amplifier. The control unit (10) LASER LDS Dactron, accelerometers (8, 12) - 4533-B and press equipment - PM-10 MG-4 were also used. The test samples were kept in the test room for 3 hours. Then, the prepared samples of the investigated material 4 were installed on the table 14 of the vibrator 1 at equal distances from each other and so that the distance to the edge of the table 14 was 10 mm. Then we set up the weight-bearing mass 11 on the samples so that the center of gravity of the weight 11 coincides with the geometric center of the table 14 of the vibrator 1.

The installation must be turned on, having previously installed on the power amplifier 9, the mode of automatic amplitude maintenance by means of the control unit 10. The oscillations of the vibrator table 14 are set at a frequency of 5 Hz and the amplitude of the acceleration of the prigruz. The first test is performed in order to stabilize the internal stresses in the material under a given static load. 15 minutes after the first test, a series of measurements of the same test material was carried out 4.

According to the test results, the arithmetic mean resonance frequency was determined. Using the mathematical apparatus presented below, the values of the dynamic modulus of elasticity and loss coefficient are determined.

The equation of the amplitudes of the harmonic forces acting on the weights is:

where M is the mass of the weights, Hc ² / m;

- амплитуда виброускорения пригруза, м/с²;

- amplitude of the vibration acceleration of the load, m / s ² ;

x ₂ - the amplitude of the displacement of the weights, m;

x ₁ - the amplitude of the displacement of the platform EDV, m;

k = k ₀ ⋅ (1 + jη) is the longitudinal complex rigidity of the samples of the lower and upper levels, N / m,

where k ₀ - dynamic stiffness, which without losses is determined by the formula:

and taking into account losses:

where M is the mass of the weight;

ω is the cyclic frequency.

η is the loss coefficient.

The loss factor η is determined by the formula:

- амплитуда виброускорения пригруза, м/с²;Where

- amplitude of the vibration acceleration of the load, m / s ² ;

- амплитуда виброускорения платформы, м/с²;

- amplitude of platform vibration acceleration, m / s ² ;

The dynamic modulus of elasticity of the sample material is determined by the formula:

where ƒ is the resonant frequency;

M is the mass of the weight;

h - the height of the sample under load (m)

F is the sample area (m ² ).

The test results of different materials studied are shown in the table.

Claims (1)

Installation for the study of the dynamic characteristics of sound-proof materials, containing a test press, an electrodynamic vibrator, including a table associated with the vibration exciter and installed under the upper working plate of the test press, load for the sample of the material under study, two accelerometers, one of which is connected to the table of the vibrator, and the other with weights, and measuring paths for connecting accelerometers with power amplifier, control unit and computer; characterized in that the electrodynamic vibrator is installed horizontally and sequentially with a test press, and its table is installed directly on the lower working plate of the test press and is connected to the vibrator exciter using a horizontal rod.

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